Anatomical knee prosthesis

ABSTRACT

An anatomical knee prosthesis configured to be oriented on an anatomical line of an interarticular space of the knee and not oriented on a mechanical axis as far as the interarticular space of the knee is concerned.

[0001] Previous knee prostheses in the state of the art are oriented on the so-called mechanical axis δ₁ with respect to its joint line. The mechanical axis is the line that runs vertically from the center of the head of the femur through the knee joint to the ankle. The joint lines of previous knee prosthesis implants were implanted at an angle of (β₁) 90° to this mechanical axis. The medial and lateral condyles of the femur were equally large in regard to their polycentric radius.

[0002] In reality, it is now the case that the joint line of the upper ankle joint to the tibia forms an angle (α₁) of 85°±5° ascending medially and descending laterally. Furthermore, in the region of the knee joint line, the anatomical healthy knee joint also does not form a right angle with the mechanical axis that was assumed at that time, but rather the tibial plateau descends medially by an angle (β₂) of about 3°±x or ascends laterally by 3°±x. The consequence of this is that the condyles of the femur have different radii. Laterally, the polycentric radii are somewhat smaller in the side view, while the medial condyle of the femur is distinctively larger with polycentric radii, as far as the radial diameter is concerned. The bearing surface in the a.p. plane is somewhat narrower in the case of the medial condyle of the femur, compared to the lateral condylar part. In addition, it should be noted that the tibial plateau drops by 3-7° in the dorsal direction.

[0003] Now, since the knee joint carries out an internal rotation in the course of knee flexion, the medial part of the femoral condylar structure moves ventrally (uphill, so to speak, with respect to the tibial plateau), whereas the lateral part of the condylar structure of the femur moves dorsally and thus downhill, so to speak. The 3° axis in the knee joint (towards the old mechanical axis δ₁), which is already present anyway, is thus indirectly enlarged, so that the tibial plateau no longer forms an angle of 3° with the original old mechanical axis δ₁, but rather now forms an angle of 3°+x, which then corresponds approximately to the angle of the upper ankle joint in relation to the former mechanical axis, i.e., generally about 5°.

[0004] Of course, independently of this, these polycentric radii also have an effect on the point of attachment of the collateral ligaments, which must be continually under tension, such that by changing the anatomical conditions by creating two equally large femoral condyles and a horizontal tibial plateau, conditions that differ completely from the anatomy are created here for the collateral ligaments as well. For this reason, the further inventive step of developing an anatomical knee prosthesis is taken here, which is intended to take these anatomical conditions exactly into account. All of the problems are solved by the features specified in the claims.

[0005] The essential features of this knee prosthesis include, first, the femoral condyles with differently pronounced polycentric condylar parts, such that the medial condylar part has a larger polycentric radius than the lateral part, so that an angle of about 3° to the mechanical axis (old mechanical axis δ₁) is achieved here, which means, assuming that a femoral medullary space stem is to be fixed to the implant, that this must have an angle of about 10° to the shaft and not, as in the old prostheses, an angle γ of 7°. As in the anatomical specimen, the medial part of the condyle of the femur may be narrower in its bearing surface than the lateral part of the condyle of the femur. Optionally, the femoral condylar components may also be individually assembled medially and laterally as units in the sense of a unicondylar sliding prosthesis, in which case a patellar shield may also be optionally added in the front. The tibial plateau must be anatomically implanted, i.e., descending dorsally by 3-7°, descending medially by about 3°, and, with respect to the bearing surface, more pronounced medially than laterally. To be able to produce the medially descending angle of 3°, the tibial plateau can then be provided with a stem, which forms an angle of 87° in the medial direction, or which, with a stem fixed at right angles on the tibial plateau implant, is inserted in the bone only at a medially descending angle of 3°±x.

[0006] Alternatively, a different polyethylene inlay level should be set on the tibial plateau metal implant with the stem fixed at right angles, so that an angle which is truer to the anatomical situation is produced by the polyethylene inlay part, which is somewhat deeper medially than laterally.

[0007] Alternatively, a rotating polyethylene monoblock with different medial and lateral levels is then also conceivable and possible. Furthermore, the tibial plateau may also be implanted as so-called unicondylar medial and lateral implants to reconstruct the anatomical downward slope in the medial and dorsal direction.

[0008] The polyethylene components must be individually insertable medially and laterally, so that the joint line, as seen from the front, i.e., from medial to lateral, is reproduced. In addition, the polyethylene inlays should have different dorsal slopes, so that in the case of a metallic tibial plateau component horizontally mounted in the lateral plane, the dorsal slope (tibial slope), which is usually different medially and laterally, is optimally reproduced.

[0009] Finally, a tibial implant variant is possible by means of a stepped resection of the tibial joint surface (medial lower than lateral) and introduction of a tibial implant with corresponding bearing surface with different height levels, which makes it possible to create a medially downward sloping tibial joint surface, with the introduction of force directed at an angle of 90° to the shaft of the tibia.

[0010] Finally, the overall effect of the present form of the knee prosthesis is to reproduce the anatomy of the healthy knee joint. As a result of the altered design of the condyles of the femur and the altered course of the joint line from earlier endoprosthetic implants, which were based on the false notion that the mechanical axis δ₁ is vertical to the talus, which does not conform to the facts, optimized knee joint kinematics are present, since the ligament stresses remain largely identical as a result of the unchanged anatomy, so that less stress is placed on the implant-bone interface.

LIST OF REFERENCE NUMBERS

[0011]FIG. 1:

[0012] 1=mechanical axis δ₁

[0013] 2=anatomical line of the interarticular space of the knee

[0014]FIG. 2:

[0015] 1=lateral

[0016] 2=medial

[0017] 3=polyethylene

[0018] 4=metal

[0019] 5=stem

[0020] FIG 3:

[0021] 1=lateral

[0022] 2=medial

[0023] 3=angle<90°

[0024] FIG 4:

[0025] 1=lateral

[0026] 2=medial

[0027] 3=bearing surface=width greater medially than laterally

[0028] 4=angle<90°

[0029]FIG. 5:

[0030] 1=lateral

[0031] 2=medial

[0032]FIG. 6:

[0033] 1=lateral

[0034] 2=medial

[0035] 3=polyethylene inlays with different heights

[0036]FIG. 8:

[0037] 1=lateral

[0038] 2=medial

[0039]FIG. 9:

[0040] 1=lateral

[0041] 2=medial

[0042]FIG. 10:

[0043] 1=lateral

[0044] 2=medial

[0045]FIG. 12a:

[0046] 1=lateral

[0047] 1=medial

[0048]FIG. 12b:

[0049] 1=lateral

[0050] 2=medial

[0051]FIG. 13a:

[0052] 1=lateral

[0053] 2=medial

[0054]FIG. 13b:

[0055] 1=lateral

[0056] 2=medial 

1-14. (Canceled)
 15. An anatomical knee prosthesis configured to be oriented on an anatomical line of an interarticular space of the knee and not oriented on a mechanical axis as far as the interarticular space of the knee is concerned.
 16. The anatomical knee prosthesis according to claim 15, comprising a medially descending tibial implant, and a femur implant with medially and laterally different-sized polycentric radii.
 17. The anatomical knee prosthesis according to claim 16, wherein the implants are configured so that, after implantation, a femur shaft and a tibia shaft form an angle of 5-7° valgus.
 18. The anatomical knee prosthesis according to claim 16, wherein the femur has condyles with differently sized polycentric condylar parts including a medial condylar part with a different polycentric radius from a lateral condylar part, so that, with respect to a joint bearing surface, a medially descending angle of 3°±x to the mechanical axis is achieved.
 19. The anatomical knee prosthesis according to claim 16, wherein the femur has condyles arranged medially and laterally relative to each other so that, even with a common polycentric radii, a lateral condylar bearing surface is displaced proximally (towards the head) and ventrally (towards the front) relative to a medial condylar bearing surface.
 20. The anatomical knee prosthesis according to claim 17, wherein the bearing surface of the femoral condylar part has different widths medially and laterally.
 21. The anatomical knee prosthesis according to claim 17, wherein the femoral condylar parts are individually assembled medially and laterally as units in the sense of a unicondylar sliding prosthesis.
 22. The anatomical knee prosthesis according to claim 21, and further comprising a patellar shield.
 23. The anatomical knee prosthesis according to claim 16, wherein the tibial implant has a tibial plateau anatomically implanted so as to generate a medially descending angle of 3°±x.
 24. The anatomical knee prosthesis according to claim 23, wherein the tibial implant is implanted to descend dorsally by 3-10°, descend medially by 3°±x**, and, with respect to the bearing surface, more pronounced medially than laterally.
 25. The anatomical knee prosthesis according to claim 22, wherein the tibial plateau is provided with a stem, which forms an angle of 87°±x in the medial direction.
 26. The anatomical knee prosthesis according to claim 22, wherein the tibial plateau has a stem fixed at right angles on the tibial plateau implant that is inserted in the bone only at a medially descending angle of 3°±x.
 27. The anatomical knee prosthesis according to claim 26, wherein the tibial plateau implant is metal and a different polyethylene inlay level is set on the tibial plateau metal implant with the stem fixed at right angles so that an angle which is truer to the anatomical situation is produced by the polyethylene inlay part, which is somewhat deeper medially.
 28. The anatomical knee prosthesis according to claim 15, including a rotating polyethylene monoblock with different medial and lateral levels.
 29. The anatomical knee prosthesis according to claim 15, wherein a tibial plateau is implanted as an unicondylar medial and lateral implant to reconstruct the anatomical downward slope in the medial and dorsal direction, so that the dorsal slope may have a different angle of slope medially and laterally.
 30. The anatomical knee prosthesis according to claim 29, wherein polyethylene components are individually inserted medially and laterally, so that the joint line, as seen from medial to lateral is reproduced.
 31. The anatomical knee prosthesis according to claim 27, wherein the polyethylene inlays have different dorsal slopes, so that in the case of a metallic tibial plateau component horizontally mounted in the lateral plane, the dorsal slope (tibial slope), which is usually different medially and laterally, is optimally reproduced.
 32. The anatomical knee prosthesis according to claim 16, wherein the tibial joint has a joint surface with a stepped resection, the tibial implant having a corresponding bearing surface with different height levels so as to create a medially downward sloping tibial joint surface.
 33. The anatomical knee prosthesis according to claim 18, wherein the condylar bearing surface is arranged so that the joint surface is lower (more distal) medially than laterally.
 34. The anatomical knee prosthesis according to claim 33, wherein the joint surface is constructed from the lateral to the medial at an angle a to the bearing axis.
 35. The anatomical knee prosthesis according to claim 33, wherein the joint surface is constructed by medial and lateral bearing surfaces with different height levels, each of which forms a 90° angle to the bearing axis. 